US20050231729A1 - Method and apparatus for continuous readout of Fabry-Perot fiber optic sensor - Google Patents
Method and apparatus for continuous readout of Fabry-Perot fiber optic sensor Download PDFInfo
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- US20050231729A1 US20050231729A1 US11/105,651 US10565105A US2005231729A1 US 20050231729 A1 US20050231729 A1 US 20050231729A1 US 10565105 A US10565105 A US 10565105A US 2005231729 A1 US2005231729 A1 US 2005231729A1
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01B—MEASURING LENGTH, THICKNESS OR SIMILAR LINEAR DIMENSIONS; MEASURING ANGLES; MEASURING AREAS; MEASURING IRREGULARITIES OF SURFACES OR CONTOURS
- G01B9/00—Measuring instruments characterised by the use of optical techniques
- G01B9/02—Interferometers
- G01B9/02015—Interferometers characterised by the beam path configuration
- G01B9/02023—Indirect probing of object, e.g. via influence on cavity or fibre
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01B—MEASURING LENGTH, THICKNESS OR SIMILAR LINEAR DIMENSIONS; MEASURING ANGLES; MEASURING AREAS; MEASURING IRREGULARITIES OF SURFACES OR CONTOURS
- G01B9/00—Measuring instruments characterised by the use of optical techniques
- G01B9/02—Interferometers
- G01B9/02001—Interferometers characterised by controlling or generating intrinsic radiation properties
- G01B9/02002—Interferometers characterised by controlling or generating intrinsic radiation properties using two or more frequencies
- G01B9/02004—Interferometers characterised by controlling or generating intrinsic radiation properties using two or more frequencies using frequency scans
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01D—MEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
- G01D5/00—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable
- G01D5/26—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light
- G01D5/268—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light using optical fibres
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01D—MEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
- G01D5/00—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable
- G01D5/26—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light
- G01D5/32—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light with attenuation or whole or partial obturation of beams of light
- G01D5/34—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light with attenuation or whole or partial obturation of beams of light the beams of light being detected by photocells
- G01D5/353—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light with attenuation or whole or partial obturation of beams of light the beams of light being detected by photocells influencing the transmission properties of an optical fibre
- G01D5/35303—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light with attenuation or whole or partial obturation of beams of light the beams of light being detected by photocells influencing the transmission properties of an optical fibre using a reference fibre, e.g. interferometric devices
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01L—MEASURING FORCE, STRESS, TORQUE, WORK, MECHANICAL POWER, MECHANICAL EFFICIENCY, OR FLUID PRESSURE
- G01L9/00—Measuring steady of quasi-steady pressure of fluid or fluent solid material by electric or magnetic pressure-sensitive elements; Transmitting or indicating the displacement of mechanical pressure-sensitive elements, used to measure the steady or quasi-steady pressure of a fluid or fluent solid material, by electric or magnetic means
- G01L9/0041—Transmitting or indicating the displacement of flexible diaphragms
- G01L9/0076—Transmitting or indicating the displacement of flexible diaphragms using photoelectric means
- G01L9/0077—Transmitting or indicating the displacement of flexible diaphragms using photoelectric means for measuring reflected light
- G01L9/0079—Transmitting or indicating the displacement of flexible diaphragms using photoelectric means for measuring reflected light with Fabry-Perot arrangements
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- G01—MEASURING; TESTING
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- G01B2290/00—Aspects of interferometers not specifically covered by any group under G01B9/02
- G01B2290/25—Fabry-Perot in interferometer, e.g. etalon, cavity
Definitions
- the present invention relates to a Fabry-Perot fiber optic sensor and, more particularly, to a high finesse Fabry-Perot sensor and tunable laser combination system for measuring small displacements.
- Low finesse Fabry-Perot interferometers have a reflectivity of approx. 50% or less. Such interferometers have been used in sensors in order to provide an indication as to the displacement of a gap between two reflective surfaces.
- U.S. Pat. No. 5,276,501 to McClintock et al. describes a low-finesse Fabry-Perot fiber optic sensor that uses a laser of limited tuning range. The laser itself is tuned via temperature control to operate at two different wavelengths.
- reflectivity of the sensor is in the range of 4%, and the readout from the sensor is approximated as a two beam interferometer so that the gap length is a function of wavelength difference and the interference from the additional multiple reflected beams is neglected.
- the present invention addresses the aforementioned needs within the industry by providing an accurate system using a tunable laser light source and a Fabry-Perot sensor configured as a transducer.
- the Fabry-Perot sensor receives and modulates the laser light, and the light is tunable over a range of frequencies.
- the modulated light is then detected via an InGaAs element (or similar detector means sensitive to the selected wavelengths of the laser).
- the detector generates a signal based upon the intensity ratio of the modulated laser light, and the detector signal is fed to the signal conditioner.
- the temperature of the Fabry-Perot sensor in the pressure transducer may be monitored with a second Fabry-Perot temperature sensor.
- the detector signal, and optionally the temperature signal, are provided to a signal conditioner, which identifies two frequency minima in the intensity ratio and generates an output indicative of displacement between the reflective surfaces of the transducer.
- the frequency range of the tunable laser is between 187.5 THz and 200 THz (or 1500 to 1600 nm in wavelength).
- a method for monitoring and quantitatively measuring small displacements in a Fabry-Perot sensor includes interrogating the reflective surfaces bounding a variable unknown gap in the Fabry-Perot sensor using a frequency-tunable laser light.
- the laser light is provided over a range of frequencies, and the intensity of the laser light modulated by the Fabry-Perot sensor is monitored to identify at least two minima.
- An absolute value of the distance of the unknown gap can then be calculated from these minima.
- the absolute value for the unknown variable gap may be used to calculate and monitor an environmental parameter of the Fabry-Perot sensor—most likely the pressure applied to one of the reflective surfaces in the sensors.
- Optional temperature correction and/or laser pulsing can be performed to enhance the performance of the system. Additional interrogation of the sensor over a reduced range of laser frequencies for fast scan monitoring of the variable gap is also contemplated.
- FIG. 1 is a schematic representation of the present invention.
- FIG. 2 is a cross sectional representation of the Fabry-Perot sensor used in the present invention.
- FIG. 3 is a plot of the intensity of the tunable laser light versus the frequency of the tunable laser light when the gap of the Fabry-Perot sensor is equal to 60,062 nm.
- FIG. 4 is similar to the plot of FIG. 3 , excepting that FIG. 4 shows the intensity versus frequency plots over a range of differing gaps.
- FIG. 5 shows a plot of the Fabry-Perot sensor gap versus the frequency difference.
- FIG. 6 shows an alternate transducer design wherein the diaphragm is replaced with a plug configuration.
- This invention is a new approach for using fiber optic Fabry-Perot sensors to make high-resolution temperature and pressure measurements at long distances between the sensor and the signal conditioning system.
- the approach requires a high power, tunable laser that can provide rapid switching in fine increments in narrow wavelength bands with repeatability in the infrared spectral band from 1500 to 1600 nm.
- Such tunable lasers with very wide tuning range have recently become commercially available.
- high resolution pressure and temperature measurements can be made using Fabry-Perot sensors at remote distances in excess of 10000 meters with update rates of 10 Hz.
- FIG. 1 A schematic of the invention 10 is shown in FIG. 1 .
- Infrared light from the laser L is injected into a multimode optical fiber (50 ⁇ m/125 ⁇ m for example), where it passes through a power splitter and thence to two sensors S p and S T —one for pressure and one for temperature, respectively.
- a multimode optical fiber 50 ⁇ m/125 ⁇ m for example
- sensors S p and S T one for pressure and one for temperature, respectively.
- each sensor S p , S T may be interrogated at two different wavelength bands within the tuning range of the laser L. If not, then separate tunable lasers with different tuning ranges may be used.
- Infrared light is reflected from the sensors S p , S T back to the detector D 1 where the light signal is converted to a photocurrent and amplified for processing in a signal conditioner (not shown) connected to the detector.
- the second Fabry-Perot temperature sensor S T is provided to track the temperature of the Fabry-Perot pressure sensor. The output of the temperature sensor S T can be used to correct the pressure sensor output for temperature dependent changes in the pressure sensor gap S p .
- the Fabry-Perot pressure sensor S p is shown in FIG. 2 , specifically configured as a diaphragm-type pressure transducer S PD .
- the general pressure sensor S P may be configured as a transducer without a diaphragm in other ways, as further described in FIG. 6 below.
- Infrared light from the tunable laser source is transmitted to the Fabry-Perot sensor through an optical fiber F.
- the Fabry-Perot senor S PD consists of two reflective surfaces 12 , 14 separated by a gap G.
- the first reflector 12 may be the end of the fiber with a reflective coating or a separate window with reflective coating.
- the first reflector 12 is separated from the pressure diaphragm 16 and the second reflector 14 by a gap distance G, which is equal to 80 ⁇ m when no pressure is applied for the preferred embodiment.
- the two parallel reflectors 12 , 14 separated by gap G comprise a high finesse Fabry-Perot (F-P) interferometer.
- the pressure transducer S PD may be configured as a circular steel (e.g. Inconel-718) plate (diaphragm) welded around the circumference of the plate to the steel sensor body.
- I R The infrared light intensity reflected back to the signal conditioner from the F-P cavity is modulated as the diaphragm deflects and the gap G changes.
- FIG. 4 Shown in FIG. 4 is a plot of the intensity ratio I R ( ⁇ ,G) for various gaps. Each curve in FIG. 4 represents a different gap. As in FIG.
- the reflected intensity ratio measured by the photodiode D 1 oscillates through maxima and minima as the laser frequency is tuned through its range. It is important to note from FIG. 4 that for any given gap, the plot of intensity ratio versus frequency is unique. Although the function in Equation 3 is oscillatory, the period is not repetitive, which means that the spectrum at some gap Ga does not overlay any other spectrum for any other gap Gn. Thus, measurement of the separation of the minima or maxima in frequency space uniquely determines the gap to within the system resolution.
- the transducer should be designed to deflect 20 ⁇ m and the deflection range is 80 ⁇ m to 60 ⁇ m. It is necessary that for all gaps in the range 60 to 80 ⁇ m, there must be at least two minima in the F-P modulated spectrum (see FIG. 3 ) within the laser tuning range.
- the minimum length of the gap depends on the laser operating wavelength and tuning range. For a given wavelength, the wider the tuning range the shorter the minimum allowed gap may be.
- the radius and thickness of the diaphragm 16 can be chosen so that at pre-determined deflection distance (and its resulting the maximum stress, S) will be well below the yield strength of the material. Selection of a low stress is also significant because it provides a very repeatable pressure sensor with little or no hysteresis.
- hysteresis refers to the graph of sensor gap versus pressure. If hysteresis is present, the gap will follow two different paths—one path when the pressure increases and a different path when the pressure decreases.
- sensor S PS An alternate for sensor S P is shown as sensor S PS in FIG. 6 .
- the transduction mechanism is created by the compression of an tubular sleeve 20 with a plug 22 in one end.
- Sleeve 22 is also fitted around the transducer body 24 .
- Reflective surfaces can be provided on fiber F and plug 22 , respectively, as discussed above. With this design there is no bending which occurs in the diaphragm design S PD . The resulting stress is a fraction of the stress in a diaphragm and results in a more repeatable and durable transducer/sensor.
- the minimum gap is approximately 60 um.
- the minimum length of the gap will depend on the laser's operating wavelength and tuning range. For any given wavelength, a wider tuning range results in a shorter minimally-allowable gap.
- an algorithm which determines the gap from the measured data and this algorithm requires that for all gaps there exist at least two minima in the F-P modulated spectrum over the tuning range.
- Equation 4 defines the spacing between the minima or spacing between the maxima plotted in FIGS. 3 and 4 . Note that for any curve plotted in FIG. 4 , the spacing of the maximum and minimum is unique.
- a laser with a 5.2 THz tuning range that is shining on the Fabry-Perot sensor gap (see FIG. 1 ). Tune the laser over its range 192.3 THz to 197.5 THz as indicated in FIG. 3 . Two minima and two maxima in the reflected light intensity are observed. A precise measurement of the spacing ⁇ between the minima defines the gap G.
- Table 1 Several examples are provided in Table 1.
- a calibration plot of sensor gap versus ⁇ is shown in FIG. 5 .
- Equation 4 The smallest change in the gap that can be measured is determined from Equations 4 and 5.
- a deflection resolution of 0.04 nm equates to a pressure resolution of 0.04 psi.
- Sensor gap (G) range is 60000 nm to 80000 nm, and the corresponding pressure range is 20000 psi to 0 psi.
- a dither operation enables tracking of a minimum in the intensity ratio.
- the sensor interrogation system consists of a tunable laser that can provide 40,000 separate and adjacent frequency outputs over the band 192.3 THz to 197.5 THz and a photodiode to measure the light intensity reflected from the Fabry-Perot gap in a pressure sensor.
- the system can provide pressure measurement accuracy less than 0.1 psi.
- a second Fabry-Perot temperature sensor S PT may also be provided as shown in FIG. 1 , although the essence of the invention focuses on the discovery of the non-repetitive nature of the response (as described above).
- the output of the temperature sensor can be used to correct the pressure sensor output for temperature dependent changes in the pressure sensor gap.
- the senor may be 5 km, 10 km or 15 km away from the signal conditioner.
- high output power is needed.
- An output power of 1 mW is sufficient and 10 mW is typically available from tunable laser systems.
- Such large power presents a fundamental problem however.
- An optical time domain reflectometer (OTDR) experiences the same problem, which is why there is a dead band for the first few meters when using an OTDR.
- the large scattered light signal saturates the detector.
- One method to minimize or reduce the effect is to pulse the light source.
- the laser If the laser is turned on and off, then for example, if the range is 10 km, the laser can be turned on for 50 ⁇ s and off for 50 ⁇ s.
- the detector can be synchronized with the laser so that when the laser is on the detector is off and when the laser is off the detector is on. For the 50 ⁇ s when the laser is on the light travels to the sensor and the detector sees no noise since it is off. For the second 50 ⁇ s, the laser is off and the detector sees infrared light reflected from the sensor.
- the laser light is on half the time and off half the time (50% duty cycle) and the detector noise is minimized because it is not exposed to scattered light. If the laser and detector on-time and off-time are continuously adjustable from 25 to 75 ⁇ s, then it is possible to adjust for any sensor range between 5 and 15 km.
Abstract
Description
- The present invention relates to a Fabry-Perot fiber optic sensor and, more particularly, to a high finesse Fabry-Perot sensor and tunable laser combination system for measuring small displacements. This application claims the benefit of U.S. Ser. No. 60/562,430, filed Apr. 15, 2004.
- Low finesse Fabry-Perot interferometers have a reflectivity of approx. 50% or less. Such interferometers have been used in sensors in order to provide an indication as to the displacement of a gap between two reflective surfaces. For example, U.S. Pat. No. 5,276,501 to McClintock et al. describes a low-finesse Fabry-Perot fiber optic sensor that uses a laser of limited tuning range. The laser itself is tuned via temperature control to operate at two different wavelengths. Notably, reflectivity of the sensor is in the range of 4%, and the readout from the sensor is approximated as a two beam interferometer so that the gap length is a function of wavelength difference and the interference from the additional multiple reflected beams is neglected. While this type of two-beam interferometer approximation may serve the purposes of the McClintock patent, the inventors have accounted for the fact that interference patterns from Fabry-Perot interferometers are not periodic. Consequently, the teachings of the McClintock patent do not apply to Fabry-Perot sensors in the art, especially with respect to the methodology used to perform the calculation of gap length.
- Notably, both with respect to the McClintock patent and the other prior references known to the inventors, the range of gaps measurable by prior art laser-based Fabry-Perot sensors were limited in practice by the wavelength and tuning range of the laser. Other errors in such systems resulted from laser instabilities and inability to precisely measure and control laser wavelength.
- Given the above limitations and shortcomings of the prior art, a system that is capable of measuring absolute values and monitor small changes in gaps in real time (i.e., at fast scan rates exceeding 2 Hz) would be welcome by the industry. Moreover, a high-finesse system to enable accurate calculations according to true Fabry-Perot equations is needed.
- The present invention addresses the aforementioned needs within the industry by providing an accurate system using a tunable laser light source and a Fabry-Perot sensor configured as a transducer. The Fabry-Perot sensor receives and modulates the laser light, and the light is tunable over a range of frequencies. The modulated light is then detected via an InGaAs element (or similar detector means sensitive to the selected wavelengths of the laser). The detector generates a signal based upon the intensity ratio of the modulated laser light, and the detector signal is fed to the signal conditioner. To insure accuracy, the temperature of the Fabry-Perot sensor in the pressure transducer may be monitored with a second Fabry-Perot temperature sensor. The detector signal, and optionally the temperature signal, are provided to a signal conditioner, which identifies two frequency minima in the intensity ratio and generates an output indicative of displacement between the reflective surfaces of the transducer. Preferably, the frequency range of the tunable laser is between 187.5 THz and 200 THz (or 1500 to 1600 nm in wavelength).
- A method for monitoring and quantitatively measuring small displacements in a Fabry-Perot sensor is also contemplated. The method includes interrogating the reflective surfaces bounding a variable unknown gap in the Fabry-Perot sensor using a frequency-tunable laser light. The laser light is provided over a range of frequencies, and the intensity of the laser light modulated by the Fabry-Perot sensor is monitored to identify at least two minima. An absolute value of the distance of the unknown gap can then be calculated from these minima. In turn, the absolute value for the unknown variable gap may be used to calculate and monitor an environmental parameter of the Fabry-Perot sensor—most likely the pressure applied to one of the reflective surfaces in the sensors. Optional temperature correction and/or laser pulsing can be performed to enhance the performance of the system. Additional interrogation of the sensor over a reduced range of laser frequencies for fast scan monitoring of the variable gap is also contemplated.
-
FIG. 1 is a schematic representation of the present invention. -
FIG. 2 is a cross sectional representation of the Fabry-Perot sensor used in the present invention. -
FIG. 3 is a plot of the intensity of the tunable laser light versus the frequency of the tunable laser light when the gap of the Fabry-Perot sensor is equal to 60,062 nm. -
FIG. 4 is similar to the plot ofFIG. 3 , excepting thatFIG. 4 shows the intensity versus frequency plots over a range of differing gaps. -
FIG. 5 shows a plot of the Fabry-Perot sensor gap versus the frequency difference. -
FIG. 6 shows an alternate transducer design wherein the diaphragm is replaced with a plug configuration. - This invention is a new approach for using fiber optic Fabry-Perot sensors to make high-resolution temperature and pressure measurements at long distances between the sensor and the signal conditioning system. The approach requires a high power, tunable laser that can provide rapid switching in fine increments in narrow wavelength bands with repeatability in the infrared spectral band from 1500 to 1600 nm. Such tunable lasers with very wide tuning range have recently become commercially available. By operating in the 1500 to 1600 nm spectral band where attenuation in optical fiber is very low, high resolution pressure and temperature measurements can be made using Fabry-Perot sensors at remote distances in excess of 10000 meters with update rates of 10 Hz.
- A schematic of the
invention 10 is shown inFIG. 1 . Infrared light from the laser L is injected into a multimode optical fiber (50 μm/125 μm for example), where it passes through a power splitter and thence to two sensors Sp and ST—one for pressure and one for temperature, respectively. Provided the tuning range of the laser is wide enough, then each sensor Sp, ST may be interrogated at two different wavelength bands within the tuning range of the laser L. If not, then separate tunable lasers with different tuning ranges may be used. Infrared light is reflected from the sensors Sp, ST back to the detector D1 where the light signal is converted to a photocurrent and amplified for processing in a signal conditioner (not shown) connected to the detector. The second Fabry-Perot temperature sensor ST is provided to track the temperature of the Fabry-Perot pressure sensor. The output of the temperature sensor ST can be used to correct the pressure sensor output for temperature dependent changes in the pressure sensor gap Sp. - By way of example, the Fabry-Perot pressure sensor Sp is shown in
FIG. 2 , specifically configured as a diaphragm-type pressure transducer SPD. As known in the art, the general pressure sensor SP may be configured as a transducer without a diaphragm in other ways, as further described inFIG. 6 below. Infrared light from the tunable laser source is transmitted to the Fabry-Perot sensor through an optical fiber F. The Fabry-Perot senor SPD consists of tworeflective surfaces first reflector 12 may be the end of the fiber with a reflective coating or a separate window with reflective coating. In either case, thefirst reflector 12 is separated from thepressure diaphragm 16 and thesecond reflector 14 by a gap distance G, which is equal to 80 μm when no pressure is applied for the preferred embodiment. Also, preferably thefirst reflector 12 is coated with a high reflectance (R=99%) dielectric coating and thesecond reflector 14 is coated with gold (R=98.5%). Together, the twoparallel reflectors - Infrared light reflected from the F-P cavity and gap G returns to the signal conditioner (see
FIG. 1 ) where it is detected by the photodiode detector D1. The detector material is InGaAs, which is sensitive in the infrared wavelength band of interest (1500-1600 nm). The pressure transducer SPD may be configured as a circular steel (e.g. Inconel-718) plate (diaphragm) welded around the circumference of the plate to the steel sensor body. When external pressure is applied to thediaphragm 16, it deflects toward thefirst reflector 12 and the gap G decreases. The radius and thickness of thepressure diaphragm 16 are chosen so that stresses that result are much less than the yield strength of the material. Under these conditions, the deflection d of the center of thediaphragm 16 is a linear function of applied pressure P give by the equation
d=0.2(Pr 4)/(Et 3) (1) -
- where
- r is the diaphragm radius
- t is the diaphragm thickness
- E is Young's modulus of the diaphragm material
- where
- For a typical working design
-
- at P=20000 psi
- d=8.2×10−4 inch (21 μm)
- r=0.3 inch
- t=0.105 inch
- E=29×106 psi
- The maximum stress S is given by
- The infrared light intensity reflected back to the signal conditioner from the F-P cavity is modulated as the diaphragm deflects and the gap G changes. The ratio of the incident-to-reflected intensity IR is a function of both the laser frequency and the gap G and is given by
-
- where
- c=λν is the velocity of light
- ν=1.93×1014 Hz is the frequency of the infrared light
- λ=1550×10−9 m (1550 nm) is the wavelength
- G is the Fabry-Perot gap distance between the first and second reflectors
- F=4R/(1−R)2
- R=(R1R2)1/2 is the composite reflectance of fiber end (R1) and diaphragm (R2)
- where
- For illustration purposes in the remaining
FIGS. 3 and 4 , a composite reflectance of R=30% is assumed, although in the preferred embodiment R>99%. Shown inFIG. 3 is a plot of the intensity ratio IR(ν,G) for a single gap G=60.062 μm. Notably, such an intensity ratio can be generated by normalizing light L provided to sensor SP (and ST, if appropriate), preferably through the use of detector D2. Shown inFIG. 4 is a plot of the intensity ratio IR(ν,G) for various gaps. Each curve inFIG. 4 represents a different gap. As inFIG. 3 for any given gap G, the reflected intensity ratio measured by the photodiode D1 oscillates through maxima and minima as the laser frequency is tuned through its range. It is important to note fromFIG. 4 that for any given gap, the plot of intensity ratio versus frequency is unique. Although the function in Equation 3 is oscillatory, the period is not repetitive, which means that the spectrum at some gap Ga does not overlay any other spectrum for any other gap Gn. Thus, measurement of the separation of the minima or maxima in frequency space uniquely determines the gap to within the system resolution. - Significantly, the inventors were the first to identify and exploit this variation in the intensity ratio versus frequency, as described in Equation 3. Previous methods had presumed this dependence was repetitive. Consequently, these previous methods could not achieve the level of precision for absolute, quantitative measurements attained by the present invention. Moreover, these previous systems could not achieve the fast scan monitoring performed by the present invention.
- To maximize the resolution of the system, it is important to match the range of gaps with the tuning range of the laser. For example, given a laser with a tuning range of 20 nm, and a transducer with starting gap at 0 psi pressure of 80 μm, then at 20000 psi pressure, the transducer should be designed to deflect 20 μm and the deflection range is 80 μm to 60 μm. It is necessary that for all gaps in the range 60 to 80 μm, there must be at least two minima in the F-P modulated spectrum (see
FIG. 3 ) within the laser tuning range. The minimum length of the gap depends on the laser operating wavelength and tuning range. For a given wavelength, the wider the tuning range the shorter the minimum allowed gap may be. - Note that the radius and thickness of the diaphragm 16 (as illustrated in the example above, a flat Inconel-718) can be chosen so that at pre-determined deflection distance (and its resulting the maximum stress, S) will be well below the yield strength of the material. Selection of a low stress is also significant because it provides a very repeatable pressure sensor with little or no hysteresis. As used here, hysteresis refers to the graph of sensor gap versus pressure. If hysteresis is present, the gap will follow two different paths—one path when the pressure increases and a different path when the pressure decreases.
- An additional source of non-repeatability occurs when the stress in the diaphragm approaches the yield point of the material. When this occurs, the sensor will not produce repeatable results and will need recalibration. Thus, it is desirable to design the transducer SPD so that the stress never approaches the yield point and for this reason, alternate transducer designs would be of great value.
- An alternate for sensor SP is shown as sensor SPS in
FIG. 6 . The transduction mechanism is created by the compression of antubular sleeve 20 with aplug 22 in one end.Sleeve 22 is also fitted around thetransducer body 24. Reflective surfaces can be provided on fiber F and plug 22, respectively, as discussed above. With this design there is no bending which occurs in the diaphragm design SPD. The resulting stress is a fraction of the stress in a diaphragm and results in a more repeatable and durable transducer/sensor. - In the example shown with a tunable laser that operates over the wavelength range 1500 to 1600 nm (which corresponds to a frequency range of 200 THz to 187.5 THz, respectively speaking), it is necessary to design both the pressure and temperature sensors so the minimum gap is approximately 60 um. For all gaps in the range, there must be at least two minima in the F-P modulated spectrum (see
FIG. 3 ) within the laser tuning range, and the minimum length of the gap will depend on the laser's operating wavelength and tuning range. For any given wavelength, a wider tuning range results in a shorter minimally-allowable gap. Later we define an algorithm which determines the gap from the measured data and this algorithm requires that for all gaps there exist at least two minima in the F-P modulated spectrum over the tuning range. - Consider the well-known relationship for a Fabry-Perot (reference Born and Wolf, Principles of Optics) with mirror separation G
Δν=c/2G (4) -
- where ν is the optical frequency at wavelength λ and the velocity of light c=λν. The symbol Δ signifies a small change in the frequency ν, where Δν=ν2−ν1. It follows from the velocity of light that
Δν/ν=−Δλ/λ (5) - where ν is the light frequency and λ the wavelength. The minus sign simply means that as the frequency increases the wavelength decreases. Consider a laser with an operating frequency between 192.3 THz (λ=1560 nm) and 197.5 THz (λ=1519 nm). The laser frequency is tunable with tuning range Δν=5.2×1012 Hz. Note that 1 THz=1012 Hz. The laser is tuned in a step-wise manner and covers the range in 40000 steps where each step is given by the resolution element δ=1.3×108 Hz. The symbol δ signifies a much smaller change than the symbol Δ, but the expression in Equation 5 continues to hold. δλ, the resolution element in wavelength is calculated as
- where ν is the optical frequency at wavelength λ and the velocity of light c=λν. The symbol Δ signifies a small change in the frequency ν, where Δν=ν2−ν1. It follows from the velocity of light that
- Equation 4 defines the spacing between the minima or spacing between the maxima plotted in
FIGS. 3 and 4 . Note that for any curve plotted inFIG. 4 , the spacing of the maximum and minimum is unique. Consider a laser with a 5.2 THz tuning range that is shining on the Fabry-Perot sensor gap (seeFIG. 1 ). Tune the laser over its range 192.3 THz to 197.5 THz as indicated inFIG. 3 . Two minima and two maxima in the reflected light intensity are observed. A precise measurement of the spacing Δν between the minima defines the gap G. Several examples are provided in Table 1.TABLE 1 Fabry-Perot gap as determined from measurement of Δν ν2 THz ν1 THz Δν = c/2G THz G (nm) 195.3 193.3 2.00 75000 194.9 192.8 2.10 71429 194.8 192.5 2.30 65217 194.8 192.4 2.40 62500 195.99 193.5 2.49 60241 - As long as there are at least two minima in the intensity ratio that are observed when the laser is tuned over its range, it is always possible to measure the gap G uniquely. A calibration plot of sensor gap versus Δν is shown in
FIG. 5 . - The smallest change in the gap that can be measured is determined from Equations 4 and 5. Consider the last case in Table 1 where G=60241 nm and ν2=195.99 THz. Calculate δG corresponding to the resolution element δν=1.3×108 Hz
- For a pressure range of 20000 psi and a diaphragm deflection range of 20000 nm (gap range 80 μm to 60 μm), a deflection resolution of 0.04 nm equates to a pressure resolution of 0.04 psi.
- The following specifications are acceptable for the tunable laser of the present invention: tunable laser scans 40,000 steps in 10 sec (and can also scan 400 steps in 0.1 sec); operating scan range is 192.3 THz to 197.5 THz in Laser 1; operating scan range is 186.8 THz to 192 THz in Laser 2; step size is 1 pm/step in wavelength space or 130 MHz/step in frequency space (c=λν, where c is velocity of light, λ is laser wavelength and ν is laser frequency). Additionally, Sensor gap (G) range is 60000 nm to 80000 nm, and the corresponding pressure range is 20000 psi to 0 psi. A dither operation enables tracking of a minimum in the intensity ratio.
- An algorithm that details a step-by-step method to determine the size of gap G, and thus the applied pressure (or some other environmental parameter associated with the Fabry-Perot sensor SP), using the tunable laser L is as follows:
-
- 1. Interrogate the pressure sensor. Perform 40,000 step scan. Find the frequency minima ν1 and ν2. Store the step numbers and values of ν1 and ν2. Calculate Δν=ν1−ν2. Calculate Ga (Ga=c/(2Δν), where Ga is the gap and c is the velocity of light). Note that the location of the minima are determined to 1 pm out of 40,000 pm. The difference in the minima is known to 2 pm. Thus, the gap Ga is known to 80 pm and the pressure is known to 0.08 psi. See Equation (8). For 20,000 psi range, the pressure is determined to one part in 250,000.
- 2. Once the gap is known, the laser is tuned to the frequency minimum nearest the center of the range and laser frequency scan range is changed to 400 steps per 0.1 sec. In this mode, small changes in diaphragm deflection (pressure) can be tracked at high speed. The pressure update rate in this fast scan mode is 10 Hz.
- 3. On a periodic basis, repeat step 1.
- 4. On a periodic basis, interrogate the temperature sensor and calculate the temperature sensor gap GT(n) using a similar algorithm as in steps 1 and 2.
- 5. Apply temperature correction factor to pressure measurement.
- In summary, the sensor interrogation system consists of a tunable laser that can provide 40,000 separate and adjacent frequency outputs over the band 192.3 THz to 197.5 THz and a photodiode to measure the light intensity reflected from the Fabry-Perot gap in a pressure sensor. The system can provide pressure measurement accuracy less than 0.1 psi. A second Fabry-Perot temperature sensor SPT may also be provided as shown in
FIG. 1 , although the essence of the invention focuses on the discovery of the non-repetitive nature of the response (as described above). The output of the temperature sensor can be used to correct the pressure sensor output for temperature dependent changes in the pressure sensor gap. - In long distance applications, the sensor may be 5 km, 10 km or 15 km away from the signal conditioner. To ensure that light from the tunable laser reaches the sensor at the end of such long optical fiber cables, high output power is needed. An output power of 1 mW is sufficient and 10 mW is typically available from tunable laser systems. Such large power presents a fundamental problem however. When so much power is injected into the transmission fiber, light is scattered back to the detector. Although the percentage of light scattered back is small, the laser power is large, so that over the first 10 meters or so of fiber length, the amount of light back-scattered causes significant detector noise. An optical time domain reflectometer (OTDR) experiences the same problem, which is why there is a dead band for the first few meters when using an OTDR. The large scattered light signal saturates the detector. One method to minimize or reduce the effect is to pulse the light source.
- Light travels about 5 ns/m in optical fiber with refractive index n=1.45. Thus it takes light about 25 μs to travel 5 km, 50 μs to travel 10 km, and 75 μs to travel 15 km. If the laser is turned on and off, then for example, if the range is 10 km, the laser can be turned on for 50 μs and off for 50 μs. The detector can be synchronized with the laser so that when the laser is on the detector is off and when the laser is off the detector is on. For the 50 μs when the laser is on the light travels to the sensor and the detector sees no noise since it is off. For the second 50 μs, the laser is off and the detector sees infrared light reflected from the sensor. With continuous operation in this mode, the laser light is on half the time and off half the time (50% duty cycle) and the detector noise is minimized because it is not exposed to scattered light. If the laser and detector on-time and off-time are continuously adjustable from 25 to 75 μs, then it is possible to adjust for any sensor range between 5 and 15 km.
- Numerous methods are available to turn the detector on and off. These include a fast shutter, electro-optic modulator, or a simple electronic circuit to switch on and off the electric current to the laser.
Claims (20)
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Also Published As
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EP1586867B1 (en) | 2018-03-14 |
EP1586867A2 (en) | 2005-10-19 |
US7940400B2 (en) | 2011-05-10 |
US7492463B2 (en) | 2009-02-17 |
US20090225325A1 (en) | 2009-09-10 |
EP1586867A3 (en) | 2006-09-13 |
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